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SriniVas Sadda, MD Professor of Ophthalmology Director, Medical Retina Unit Ophthalmic Imaging Unit Doheny Image Reading Center Doheny Eye Institute University of California – Los Angeles
Future OCT Technology
RETINAL UPDATE 2015 January 31, 2015
Disclosure
• Research Grant Recipient: Optos, Carl ZeissMeditec, Optovue
• Consultant: Carl Zeiss Meditec, Optos
Limitations of existing SDOCT
•! Retinal layers are well visualized, but notindividual cells
•! Speed is adequate, but still limits scanningarea or amount of oversampling
•! Functional data still relatively limited•! Dynamic vascular (blood flow/leakage)
information is lacking•! Automatic quantitative data is limited•! Requires trained operator
Future OCT Technologies
•! Improved Resolution
•! Improved Speed
•! Improved Penetration
•! Functional Information
•! Vascular/Molecular Imaging
•! Increased Automation
OUTLINE
Future OCT Technologies
•! Improved Resolution
•! Improved Speed
•! Improved Penetration
•! Functional Information
•! Vascular/Molecular Imaging
•! Increased Automation
OUTLINE
Improving axial resolution
•! Axial resolution depends onlight source bandwidth andwavelength
Axi
al
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Improving axial resolution •! Previously broad
bandwidths only achievable with expensive femtosecond titanium sapphire lasers
•! Multiplexed superluminescent diodes (SLDs) have made UHR OCT commerically feasible (e.g. Optopol Copernicus HR)
Drexler et el, Prog Ret Eye Res 2008; 27:45-88.
International Nomenclature for OCT Meeting Consensus OCT Classification
Formed Vitreous Posterior Cortical Vitreous
Preretinal Space
Nerve Fiber Layer Ganglion Cell Layer
Inner Plexiform Layer Inner Nuclear Layer
Outer Plexiform Layer (dendritic)
OPL: axonal-dendritic junction (subtle)
Henle Fiber Layer (axonal OPL) Outer Nuclear Layer
Sattler’s Layer (inner Choroid)
Haller’s Layer (Outer Choroid)
External Limiting Membrane
Ellipsoid Zone
Outer Segments
Interdigitation Zone
Choriocapillaris
RPE/ Bruch’s Complex
Myoid Zone
Choroid Sclera
Junction
Improving transverse resolution
•! Transverse resolution is probably more important – limited to 20 microns by optical aberrations of the eye
Lateral/transverse
Improving transverse resolution
•! Transverse resolution is probably more important – limited to 20 microns by optical aberrations of the eye
Lateral/transverse Aberrations in the Eye
trefoil coma coma trefoil
quadrafoil secondary spherical secondary quadrafoil
pentafoil secondary secondarysecondary pentafoilsecondary
defocusastigmatism astigmatism
astigmatism astigmatism
trefoiltrefoil comacoma
Z20Z 2
-2 Z22
Z 3-1 Z3
1Z 3-3 Z3
3
Z40 Z4
2Z 4-2 Z4
4Z 4-4
Z51Z 5
-1 Z53Z 5
-3 Z55Z 5
-5
Lower OrderAberrations
Higher Order
Aberrations
Z 2-2 Z2
0 Z22
ConventionalOptics
Fix These
Z 3-1 Z3
1 Z33Z 3
-3
Z 4-4
Z 5-5
Z 4-2
astigmatism
Z 5-3
Z40 Z4
2 Z44
Z55Z5
3
astigmatism
Z51
astigmatismastigmatism
Z 5-1
But NotThese
Improving transverse resolution
•! Adaptive optics systems compensate for these aberrations
Courtesy: Don Miller, Indiana University
AO-OCT vs AO-SLO
From Miller, et al
AO-SLO: (+) no speckle noise; (-) poor axial AO-OCT: (+) excellent axial; (-) speckle --- but can average
From Miller, et al
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AO-OCT
•! Isotropic 3D resolution (3.5 microns x 3.5 microns x 3.5 microns)
Visualization of individual cone inner and outer segments
AO-OCT Spectralis
AO-OCT
Individual nerve fiber bundles can be seen
Future OCT Technologies
•! Improved Resolution
•! Improved Speed
•! Improved Penetration
•! Functional Information
•! Vascular/Molecular Imaging
•! Increased Automation
OUTLINE
Future OCT Technologies
•! Improved Resolution
•! Improved Speed
•! Improved Penetration
•! Functional Information
•! Vascular/Molecular Imaging
•! Increased Automation
OUTLINE
Improved Speed
•! Swept Source OCT –! Another Fourier domain OCT
technology –! 10X faster than existing SD-OCT
instruments –! Also better sensitivity with less
roll-off
From Potsaid et al, Optics Express 2010; 18: 20029.
Improved Speed
•! Swept Source OCT –! At these speeds, fixation/motion
no longer an issue –! Large areas can be scanned
quickly and with extensive averaging
From Potsaid et al, Optics Express 2010; 18: 20029.
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Large field OCT Imaging
12 mm B-scans are easy to obtain
Choroid and laminar portions of the optic nerve are well seen
Large field OCT imaging 12 x 9 mm volume scans are also easy
Zeiss SS-OCT prototype (investigational device, not FDA cleared)
Large field OCT imaging
12 x 9 mm volume scans are also easy
Produce OCT projection maps that truly resemble fundus images
Weiss ring
Zeiss SS-OCT prototype (investigational device, not FDA cleared)
Large field OCT Imaging
12 mm B-scans – visualize ON and Macula
Geographic atrophy
Vitreous imaging with SS-OCT
Better sensitivity means better visualization of subtle structures
•! Better evaluation of vitreo-macular interface disease and normal vitreous dynamics
•! Possibility of quantification of vitreous cell
Vitreous imaging with SS-OCT
Wide angle scans allow vitreous relationships between optic nerve and macula to be studied
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Vitreous imaging with SS-OCT
With SS-OCT, both the vitreous and choroid can be imaged simultaneously with brilliant detail
Large field OCT imaging •! Underlying high quality B-scan data yields
high quality OCT fundus images
Pathologic myopia with tilted nerve and PPA
Higher Sensitivity •! Very little sensitivity loss with depth
with swept source OCT –!Better signal-to-noise ratio
•! Enhances visualization of outer retinal structures
Improved Speed
•! Swept Source OCT –! Extensive averaging allows fine
structures to be seen
From Potsaid et al, Optics Express 2010; 18: 20029.
Improved Speed
From Klein et al, Optics Express 2011; 19: 3044.
•! FDML - SS OCT (Fourier domain mode – locked swept source OCT)
–! 1,368,700 A-scans/sec (“Megahertz”)
–! Ultrawidefield OCT •! 1900 x 1900 A-scans •! 3 seconds) •! 70 degree field of view
–! Can produce 4MP fundus image
Improved Speed
• FDML - SS OCT (Fourier domain mode – locked swept source OCT)
– 1,368,700 A-scans/sec (“Megahertz”)
– Ultrawidefield OCT • 1900 x 1900 A-scans • 3 seconds) • 70 degree field of view
– Can produce 4MP fundus image Can produce 4MP fundus image Can produce 4MP fundus image Can produce 4MP fundus image
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ILM to choroid-sclera ISOS to BM
Choroid 1/3 of choroid 2/3 of choroid
Choroidal imaging with SSOCT En Face Choroidal Imaging En Face Choroidal Imaging
ssOCT at 1050nm shows contrast at the level of the CC. Courtesy of Scott Fraser
ILM to choroid-sclera ISOS to BM
Choroid 1/3 of choroid 2/3 of choroid
Choroidal imaging with SSOCT
Zeiss Swept Source OCT (prototype, not yet FDA cleared)
En face imaging through retina and choroid
Zeiss SS-OCT prototype (investigational device, not FDA cleared)
Serous PED
Zeiss SS-OCT prototype (investigational device, not FDA cleared)
En face imaging through CNV
Zeiss SS-OCT prototype (investigational device, not FDA cleared)
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En face imaging through CNV Optic Nerve Head Imaging with SSOCT
Glaucomatous nerves with SSOCT
Drance hemorrhages are associated with tears in the lamina
Moderate to severe glaucoma
Glaucomatous nerves with SSOCT
Early glaucoma
En face imaging through Geographic Atrophy En face imaging through Geographic Atrophy
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High-resolution en face OCT En face slabs can be extracted from any layer of interest
En Face slabs at photoreceptor - RPE level
OD OS
Non-proliferative Diabetic Retinopathy
•! Microaneurysms visible on en face images
Zeiss SS-OCT prototype (investigational device, not FDA cleared)
Swept Source OCT and wavelength •! Most future commercial
swept source OCT devices will likely operate in the long wavelength (>1 micron) regime
•! Deeper Penetration
http://www.exalos.com/images/stories/Swept_Sources.jpg
Topcon DRI OCT-1
Future OCT Technologies
•! Improved Resolution
•! Improved Speed
•! Improved Penetration
•! Functional Information
•! Vascular/Molecular Imaging
•! Increased Automation
OUTLINE
Future OCT Technologies
•! Improved Resolution
•! Improved Speed
•! Improved Penetration
•! Functional Information
•! Vascular/Molecular Imaging
•! Increased Automation
OUTLINE
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Enhanced Depth Imaging
•! Optimizing orientation relative to the zero delay (“Spaide inversion”) and averaging are two methods to improve visualization of deeper structures
•! Increasing the imaging wavelength is another approach to achieve greater depth penetration
Importance of Choroidal Thickness
•! Choroidal thickness varies in different diseases
FCP thickness: –! Normals: 280-290 microns
–! CSCR patients: 400-500 microns
–! High Myopes: 93 microns
–! AMD/ARCA: 120 microns
OCT and wavelength •! Two “Windows of Opportunity” for retinal
OCT imaging
http://www.thorlabs.com/images/TabImages/WaterAbsorptionsm.jpg
Absorption Peak: 970nm
OCT Imaging Windows
1.! Visible to near infrared (950nm) -- BROAD
2.! 1000nm – 1100nm -- NARROWER BANDWIDTH (restricted to 100 nm) and still more absorption than at shorter wavelengths
Long wavelength (1 micron OCT)
•! Most future swept source OCT devices will likely operate in the long wavelength (>1 micron) regime
http://www.exalos.com/images/stories/Swept_Sources.jpg
Choroidal Visibility: 1050 vs 840 Comparison Study at Doheny of 105onm vs 840nm Results: •! Even when the choroid was fully-visible at 840nm, considerable additional
detail was visible at 1050nm
1050 nm 840 nm
Retinitis Pigmentosa
Orbital Fat
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Choroidal volume quantification
Hyperope Emmetrope Myope
Better Anterior Segment Imaging with 1050 nm OCT
•! Anterior Segment –!Superior visualization of angle recess and
trabecular meshwork
Better Anterior Segment Imaging with 1050 nm OCT
•! Anterior Segment –!Superior visualization of angle recess and
trabecular meshwork, corneal endothelium
Anterior segment imaging with SS-OCT
Deep penetration (1050nm) and high sensitivity of SSOCT allows visualization of full extent of lens/IOL and angle recess
Anterior segment OCT
1050nm SDOCT 840nm Cirrus SDOCT
1310nm Visante TD OCT
1050nm SSOCT
Why should you care about OCT of the angle?
•! Singer et al., Retina 2012 •! Angle configuration on OCT was highly
predictive of steroid response –! Narrower angle opening distance (termed
“angle recess width” in the paper) increased risk
Low risk for IOP response
High risk for IOP response
•! Courtesy of Michael Singer, MD
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Anterior segment imaging with SS-OCT
Iris imaging
Anterior segment imaging with SS-OCT
Iris imaging
Evaluation of the trabecular outflow system, Schlemm’s canal, and collector channels is an area of current interest
Future OCT Technologies
•! Improved Resolution
•! Improved Speed
•! Improved Penetration
•! Functional Information
•! Vascular/Molecular Imaging
•! Increased Automation
OUTLINE
Future OCT Technologies
•! Improved Resolution
•! Improved Speed
•! Improved Penetration
•! Functional Information
•! Vascular/Molecular Imaging
•! Increased Automation
OUTLINE
Future OCT Technologies
•! Improved Resolution
•! Improved Speed
•! Improved Penetration
•! Functional Information
•! Vascular/Molecular Imaging
•! Increased Automation
OUTLINE
Optophysiology
•! Dual laser approach
•! High-speed long wavelength used to obtain repeated OCT scans from same location over time, without stimulating photoreceptors
•! Separate visible light laser used to activate photoreceptors
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Optophysiology
Change in response at the IS-OS junction over time
Future OCT Technologies
•! Improved Resolution
•! Improved Speed
•! Improved Penetration
•! Functional Information
•! Vascular/Molecular Imaging
•! Increased Automation
OUTLINE
Measurement of both Doppler shift and incidence angle are needed to compute flow in a vessel
! V
Probe beam
!" /)cos(2Vv =#
vv !+v
David Huang, MD, PhD www.AIGStudy.net
Flow direction relative to OCT beam is measured by 2 parallel cross-sections
Double circular scan Flow profile and direction determined on parallel sections*
*Y. Wang, B. Bower, J. Izatt, O. Tan, D. Huang,”In vivo total retinal blood flow measurement by Fourier-domain Doppler optical coherence tomography,” Journal of Biomedical Optics 2007;12:041215-22.
David Huang, MD, PhD www.COOLLab.net
Double circular scan transects all
retinal branch
vessels 6 times per
second
Inner Circle
Outer Circle
David Huang, MD, PhD www.AIGStudy.net
!!" dxdz
#$
cos2
" Total Retinal Blood Flow
Flow in Veins
Algorithm for Total Retinal Blood Flow
0
1
2
3
4
5
0 0.5 1 1.5 2
Time (second)
Flow
(mic
rolit
er/m
inut
e)
Y. Wang, et. al., Journal of Biomedical Optics 13, 064003, (2008)
Flow value : 40.8 to 52.9 µl/min, CV: 10.5% Wang Y, et al. Br J Ophthalm, 93:634 (2009)
x
z
vessel velocity cross section
Flow in a single vessel
Average flow over 2 seconds for each vessel
Doppler angle measurement
David Huang, MD, PhD www.COOLLab.net
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Superior Branch Vein Occlusion & Proliferative Diabetic Retinopathy
Venous Flow Superior (µl/min) Inferior (µl/min)
Case 8.2 12.1 Normal mean±SD
(Range) 23.5 ± 3.0 (19.2-27.5)
22.2 ± 2.6 (19.6-27.4)
Amani Fawzi, MD
T T S N I
Non-Arteritic Anterior Ischemic Optic Neuropathy
Venous Flow Superior (µl/min)
Inferior (µl/min)
Case 12.99 19.47
Normal mean±SD (Range)
23.5 ± 3.0 (19.2-27.5)
22.2 ± 2.6 (19.6-27.4)
Alfredo Sadun, MD, PhD
Inferior altitudinal visual field defect matched with lower superior blood flow in 3/3 cases.
OCT Angiography
•! Using the complex data encoded within the OCT images (complex data is generally discarded by most commercial devices), structures with motion may be selectively isolated.
•! After eliminating Brownian motion and fixation artifact, most of the residual motion in the eye is blood flow.
Phase variance OCT
Phase Variance OCT “OCT Angiography” ADVANTAGES •! No Dye •! Depth Resolved
Collaborative work with Scott Fraser and Jeff Fingler (Caltech)
Composite image – Sadda’s Eye Undilated
Phase Variance OCT for imaging CNV
Courtesy of Jeff Fingler, Scott Fraser
Neovascular AMD, FVPED s/p >30 ranibizumab injections Old lesion – mature vessels within membrane
Deep Retinal Capillary Plexus
Phase Variance OCT for imaging CNV
Courtesy of Jeff Fingler, Scott Fraser
Neovascular AMD, FVPED s/p >30 ranibizumab injections
Retinal – Choroidal Anastomosis
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Phase Variance OCT for imaging CNV
Courtesy of Jeff Fingler, Scott Fraser
Neovascular AMD, FVPED s/p >30 ranibizumab injections
Retinal – Choroidal Anastomosis
Phase Variance OCT for imaging CNV
Courtesy of Jeff Fingler, Scott Fraser
Neovascular AMD, FVPED s/p >30 ranibizumab injections
Superficial vessels of CNV
Phase Variance OCT for imaging CNV
Courtesy of Jeff Fingler, Scott Fraser
Neovascular AMD, FVPED s/p >30 ranibizumab injections
Larger CNV Vessels
Phase Variance OCT for imaging CNV
Courtesy of Jeff Fingler, Scott Fraser
Neovascular AMD, FVPED s/p >30 ranibizumab injections
Larger CNV Vessels
PV OCT pitfalls
•! Motion artifact can be a problem for obtaining high-quality images in some patients.
•! Fixation tracking may be a key requirement for optimal imaging
PV OCT
•! Eye tracking can yield superb image quality
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OCT Angiography
Split-Spectrum Amplitude Decorrelation Angiography
SSADA
•! “Decorrelation” refers to fluctuating values of OCT intensities
•! Blood flow results in fluctuation in the amplitude of the OCT fringes as RBCs enter and exit a particular voxel
•! Greater fluctuation means greater flow Jia et al, Biomed Opt Exp 2012
SSADA •! Splitting the spectrum yields a better signal to noise ratio
Jia et al, Opt Exp 2012
En face retinal and choroidal angiograms at different Z coordinates at macula
Yali Jia, PhD; David Huang, MD, PhD. www.COOLLab.net
En face retinal and choroidal angiograms at different Z coordinates at ONH
Yali Jia, PhD; David Huang, MD, PhD. www.COOLLab.net
0.1
0.2
0.3
3
4
5
3.0
5.0
log
inte
nsity
(a.u
.)
0.1
0.3
Dec
orel
atio
n (a
.u.)
(A) (B) (C) (D)
(A) (B)
(C)
En face ONH angiograms separately showing the microcirculation within retina , choroid and lamina cribrosa
Yali Jia, PhD; David Huang, MD, PhD. www.COOLLab.net
Retina Choroid Lamina Cribosa
Slab Level
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Quantitative OCT Angiography
Flow and vessel density was reduced in glaucoma patients
Depth – resolved angiography
Courtesy: David Huang, MD PhD
Near-commercial OCT Angiography
Near-commercial OCT Angiography •! SSADA-based
–! Optovue Avanti XR
•! SD-OCT - based •! Resolution not as good as research prototypes
Vascular Detail with OCT Angiography
Zeiss SS-OCT prototype (investigational device, not FDA cleared)
Swept-source OCT OMAG - Based
Zeiss SS-OCT prototype (investigational device, not FDA cleared)
Vascular Detail with OCT Angiography
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Diabetic Retinopathy
2 patients with NPDR --- note microaneurysms and enlarged foveal avascular zone
Zeiss SS-OCT prototype (investigational device, not FDA cleared)
Diabetic Retinopathy
Zeiss SS-OCT prototype (investigational device, not FDA cleared)
Branch vein occlusion
SC_GN_183_OS BRVO
Branch vein occlusion – OCT Angiography
FA
Motion artifact lines – will be eliminated by enabling tracking
Depth resolved vascular imaging
Zeiss SS-OCT prototype (investigational device, not FDA cleared)
Superficial Retinal Capillary Plexus Level
Depth resolved vascular imaging
Zeiss SS-OCT prototype (investigational device, not FDA cleared)
Choriocapillaris Level!
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Depth resolved vascular imaging
Zeiss SS-OCT prototype (investigational device, not FDA cleared)
Future OCT Technologies
•! Improved Resolution
•! Improved Speed
•! Improved Penetration
•! Functional Information
•! Vascular/Molecular Imaging
•! Increased Automation
OUTLINE
Future OCT Technologies
•! Improved Resolution
•! Improved Speed
•! Improved Penetration
•! Functional Information
•! Vascular/Molecular Imaging
•! Increased Automation
OUTLINE
Advanced Automated Analyses •! Many groups developing algorithms for segmenting various retinal layers
oheny mage nalysis aboratory (Jewel Hu)
D I
A L
11 Layer Segmentation: Vitreous NFL GCL IPL
INL OPL ONL IS
OS RPE Choroid
Advanced Automated Analyses
•! Algorithms for segmenting specific pathologic structures already becoming available in commercial OCT software (e.g. drusen, GA analysis)
Area: 5.21 mm2
Volume: 0.899 mm3
Courtesy of Phil Rosenfeld
•! In the near future we can expect automated algorithms to segment PEDs, subretinal fluid, retinal cysts and various other retinal layers
Anterior Segment Analyses
560 µm in cornea
OCT pachymetry
-! Automated tools now available
-! Individual corneal layer thickness and volume quantification in development
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Automated Acquisition
•! Binocular self-administered OCT –! Prototype in development (Walsh/Updike)
–! Scan both eyes simultaneously from cornea to posterior pole with high-speed SS-OCT
Auto-focus Lenses
IP Distance adjustment
CPU
Z-offset reference
adjustment
!
"
#
$ % &
'
(
)
*
Z-offset reference
adjustment +
Automated Acquisition •! OCT Biomicroscopy
Anterior chamber cell/flare
Vitreous cell
Cystoid macular edema
Anterior chamber cell/flare resolved
Vitreous cell resolving
Cystoid macular edema resolved
Visit 1 Visit 2 (post-Rx)
May facilitate rapid and remote assessments which may be of use in pharmacotherapy era
Summary
•! Advances in OCT technology continue to proceed at a rapid pace.
•! These advances are addressing many of the limitations of existing devices.
•! Applications of OCT in our diagnosis and treatment of patients can be expected to continue to expand.
Thank You!